调控单位点M-N-C电催化剂的电子结构提升二氧化碳还原性能

全球的动力来源主要依靠化石能源，然而无节制地开采引起了一系列的能源危机和环境问题，例如，能源枯竭、气温逐年升高、气候恶化和海洋酸化等，这已经威胁了人类的可持续发展，因此寻找可再生能源和减缓二氧化碳的排放成为目前的关键问题，反应条件相对温和的电催化二氧化碳还原反应(CO₂RR)可将CO₂转化为具有工业价值的产品，例如C1、C2和C2+，这是解决“碳中和”的一种有效措施。电催化CO₂RR是一个复杂的多个电子/质子转移过程，反应机理相对复杂，涉及很多反应中间体，影响产物的选择性，CO₂RR的大规模应用需要开发低成本和高效的电催化剂。具有大比表面积、100%的原子利用率、不饱和配位、相对均匀的活性位点的原子分散的金属和氮共掺杂碳(M-N-C)材料是一种很有前途的催化剂。M-N-C材料具有可调变性，通过调节中心金属离子或中心金属离子的配位环境，中心金属离子的电子性质和原子结构将会发生变化，这为设计具有高效催化CO₂性能的催化剂提供了新的途径。因此，探讨在原子水平上调控M-N-C材料的电子...

Electronic Structure Regulation of Single-Site M-N-C Electrocatalysts for Carbon Dioxide Reduction

The current global population and economy depends on fossil fuel consumption; however, the uncontrolled exploitation of fossil fuels has caused a series of energy crises and environmental problems, such as energy exhaustion, annual temperature rise, climate deterioration, and ocean acidification, which have already threatened the sustainable development of all living organisms. Therefore, finding renewable and reliable energy sources as well as reducing carbon dioxide (CO₂) emissions have become the key focus in recent years. During the electrocatalytic CO₂ reduction reaction (CO₂RR) under relatively mild conditions, CO₂ is converted into valuable products, such as C1, C2, and C2+ hydrocarbons, which is an effective strategy towards realizing "carbon neutrality". Electrocatalytic CO₂RR is complex as it involves multiple electron/proton transfer processes. The reaction mechanism is also complex and involves many intermediates, which ultimately affects product selectivity. The large-scale application of the CO₂RR requires the development of cheap and efficient electrocatalysts. Atomically dispersed metal and nitrogen co-doped carbon (M-N-C) materials, with large surface areas, 100% atomic availability, unsaturated coordination, and relatively uniform active sites, are promising catalysts for the CO₂RR. M-N-C materials also have adjustable properties. For example, tuning the coordination environment of the central metal ions changes the electronic properties and atomic structures of the metal ions, which provides a new way for designing catalysts with high CO₂RR performances. Therefore, it is of great significance to investigate the effect of regulating the electronic structure of M-N-C materials at the atomic level on catalytic activity and selectivity during the CO₂RR. Additionally, the reduction potentials of the half reactions of most CO₂RR products are within ±0.2 V of the hydrogen evolution reaction (HER), and most catalysts that bind CO₂ are rich in electrons and active for the HER. Therefore, it is also necessary to design catalysts that can kinetically inhibit the competitive HER during the CO₂RR. In this review, we discuss the synthesis methods of M-N-C materials, the reaction pathways of CO₂ reduction to C1, C2, and C2+ hydrocarbons, and the main factors affecting the CO₂RR. Specifically, three strategies for regulating the electronic structures and geometric configurations of M-N-C materials are systematically reviewed, namely, the modification of the carbon base surface of M-N-C materials, selection of appropriate central metal ions, and regulation of the coordination environment of the central metal ions. The effects of different active sites on the selectivity towards various products during the catalytic CO₂RR are also discussed in detail. Finally, we highlight the current challenges and future development directions of M-N-C materials for the electrocatalytic CO₂RR.